Seedlings Face Uphill Battle with Climate Change

Some pine trees may have trouble gaining a foothold above the treeline.

Image courtesy of Kueppers et al., Global Change Biology 23, 2383-2395 (2017). Copyright 2016 John Wiley & Sons Ltd. Reprinted with permission. https://alpine.ucmerced.edu/pub/htdocs/

Research explored how warming will alter tree establishment at and above the tree line.

The Science

Scientists found that certain species of trees will not rapidly advance uphill as global temperatures rise. In other words, subalpine forests will not follow the climate up the mountain. Using field experiments in the Rocky Mountains, scientists tested how two types of emerging tree seedlings responded to artificial warming and watering at three locations. They found that Engelmann spruce may not move to higher elevations as temperatures rise. Further, the spruce may die off at lower elevations. Its overall range could shrink. The hardy limber pine may advance upward, but likely at the same slow pace as in today’s climate.

The Impact

There is little understanding of climate constraints on seedlings, which are the future of the forest. The unexpected results indicate that warming reduces the odds of seedlings establishing or provides no net benefit. Past genetic adaptation to local conditions may also hinder upslope tree advances, a finding counter to current theory.

Summary

Climate warming is expected to promote upslope shifts in forests. However, researchers working with common gardens sown with seeds collected from two different elevations and subjected to climate manipulations, using infrared heaters and manual watering, indicate that warming and local genotype may constrain tree seedling recruitment above the current treeline. Negative effects of warming in forest, treeline, and alpine sites were partly offset by watering, suggesting growing season moisture may limit establishment of future subalpine forests. Greater climate sensitivity of Engelmann spruce compared with limber pine portends potential contraction in the elevational range of Engelmann spruce and changes in the composition of high-elevation Rocky Mountain forests. The greater availability of poorer quality seed at the upper forest edge could further slow upslope shifts.

Contact

(BER PM)
Daniel Stover
SC-23.1
Daniel.Stover@science.doe.gov (301-903-0289)

(PI Contact)
Lara M. Kueppers
Research Scientist, University of California, Merced and Lawrence Berkeley National Laboratory
lkueppers@ucmerced.edu or lmkueppers@lbl.gov (510-486-5813)

Funding

This research was supported by the U.S. Department of Energy, Office of Science, Office of Biological and Environmental Research.

Publications

L.M. Kueppers, E. Conlisk, C. Castanha, A.B. Moyes, M.J. Germino, P. de Valpine, M.S. Torn, and J.B. Mitton, “Warming and provenance limit tree recruitment across and beyond the elevation range of subalpine forest.” Global Change Biology 23(6), 2383-2395 (2016). [DOI: 10.1111/gcb.13561]

Related Links

Lawrence Berkeley National Laboratory news release: Study: Warming Could Slow Upslope Migration of Trees

Highlight Categories

Program: BER , CESD

Performer: University , DOE Laboratory